USDA Database for the Choline
Content of Common Foods
Release Two
Prepared by
Kristine Y. Patterson, Seema A. Bhagwat, Juhi R. Williams,
Juliette C. Howe, and Joanne M. Holden
Nutrient Data Laboratory
写眞
Agricultural Research Service
U.S. Department of Agriculture
In collaboration with
Steven H. Zeisel, Kerry A. Dacosta, and Mei-Heng Mar
Department of Nutrition, University of North Carolina, Chapel Hill, NC 27599
January 2008
U.S. Department of Agriculture
Agricultural Research Service
Beltsville Human Nutrition Research Center
Nutrient Data Laboratory
10300 Baltimore Avenue
Building 005, Room 107, BARC – West
Beltsville, Maryland 20705 www.v/fnic/foodcomp/search
青于蓝高考语文核按钮Tel. 301-504-0630 城市生活e站
E-mail: ndlinfo@ba.v
Web site: http//www.v/nutrientdata
1Supported by the United States Department of Agriculture (59-1235-0-0059), the
National Institutes of Health (Y1-HV-8116-14, DK55865), the National Cattlemen’s Beef Association, and the National Pork Board. Support for this work was also provided
by grants from the NIH to the UNC Clinical Research Unit (DK56350) and the Center for Environmental Health (ES10126).
Table of Contents
Documentation (3)
Methods and procedures for generating the table (4)
?Data evaluation (5)
?Format of the tables (6)
?Data dissemination (7)
References cited in the documentation (7)
Chemical structures of choline and choline-containing compounds(Fig. 1) (8)
Metabolic pathway for choline compounds (Fig. 2) (9)
目诊
Total choline in selected foods (Fig. 3) (10)动力学模型
11-36
Documentation: USDA Database for the Choline Content of Common
Foods
Introduction
Research has shown that choline is important for the synthesis of phospholipids in cell membranes, methyl metabolism, acetylcholine synthesis, and cholinergic neurotransmission in humans (1). Betaine, a choline derivative, is also important because of its role in the donation of methyl groups to homocysteine to form methionine (2). Folate and choline are metabolically interrelated (1). Diminishe
d folate availability increases demand for choline as a methyl donor while decreased choline availability increases demand for folate methyl groups (3). Zeisel and colleagues, have shown that healthy males fed a choline deficient diet, with normal folate and vitamin B12 intake, became choline depleted and developed liver steatosis and liver damage that resolved when a source of dietary choline was provided (4).
In 1999, at an NIH sponsored workshop on trimethylaminuria, it was estimated that as much as one percent of the U.S. population may suffer from a genetic defect in the flavin-containing monooxygenase 3 gene, FM03, leading to development of a fishy body odor because patients or people who are affected accumulate trimethylamine (5-7). A choline restricted diet would be beneficial for this group of people as it diminishes body odor.
In 1998, the Food and Nutrition Board of the Institute of Medicine established dietary recommendations for choline intake, estimating an Adequate Intake (AI) at 550 mg per day for men and 425 mg per day for women. However, little data were available on the choline content of foods from which dietary intake levels could be calculated. Therefore, a choline database has been developed which provides researchers and consumers with the means to estimate choline intake from common foods. The collaborators for the database are the Nutrient Data Laboratory (NDL) of t
he US Department of Agriculture, Beltsville, MD and University of North Carolina at Chapel Hill, NC. This release contains about 630 food items. It replaces Release One, which was issued in March 2004.
Methods and procedures for generating the table
To generate the database for choline, food sample units of more than 630 foods were purchased, processed, and analyzed for six metabolites of choline. Most of the
samples for the project were obtained nationally from 12-24 retail outlets in accordance with the national sampling plan developed for the USDA National Food and Nutrient Analysis Program (8). Approximately 15% of the analyses were based on samples picked up locally (Chapel Hill, NC or Blacksburg, VA). Food items were homogenized and analyzed as purchased (raw) or after cooking following package directions.
The food samples were analyzed by mass spectrometry in the laboratory of S. Zeisel, University of North Carolina at Chapel Hill. Choline compounds were extracted and partitioned into organic and aqueous phases using methanol and chloroform and analyzed directly by liquid chromatography-electrospray ionization-isotope dilution mass spectrometry (LC-ESI-IDMS) (9). The chemical structur
es of the choline metabolites are shown in Fig 1. Quality assurance was monitored through the use of duplicate sampling, in-house control materials, and standard reference materials. Samples were analyzed for betaine and these choline-contributing compounds: free choline (Cho); glycerophosphocholine (GPC); phosphocholine (Pcho); phosphatidylcholine (Ptdcho); and sphingomyelin (SM).
食品价格连续上涨
The analytical data for Cho, GPC, Pcho, Ptdcho, and SM are presented individually in the database because these choline sources may differ in bioavailability and knowledge of their amounts in foods support future research (10). The metabolic pathways for the interconversion of these individual choline compounds are shown in Fig. 2. Total choline content was calculated as the sum of Cho, GPC, Pcho, Ptdcho, and SM. Individual metabolites in the database are reported as mg choline moiety per 100g of food. Betaine values are not included in the calculation of total choline, since the conversion of choline to betaine is irreversible (11). Betaine values are reported as the mg of betaine/100g food. A zero value reported in the database is a true zero; samples were analyzed, but the compound (betaine, choline, etc) was not detected. In this updated report, the betaine content of foods made from grains, such as cereal, bread, and pasta, as well as in seafood and spinach has been corrected and are significantly lower than previou
sly reported (USDA Database for the Choline Content of Common Foods, Release One). Because these are commonly consumed foods, these differences could change previous conclusions about the probable associations between dietary betaine and risk for disease. Caution should be exercised in the interpretation of the betaine values in common foods because there are likely to be considerable variations in the betaine content of plants depending on the plant variety and growing conditions (12,13); thus more data are needed on such variability. A technical problem related to the
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